Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.23.5 (cathepsin D)
4,130 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A new aspartic proteinase was isolated from porcine intestine mucosa by affinity chromatography on pepstatin-Sepharose 4B and gel filtration on Sephadex G-100. The enzyme was purified 1600-fold and appeared homogeneous upon polyacrylamide gel electrophoresis. The proteinase has a Mr 60 000 +/- 4000 Da. During sodium dodecyl sulfate polyacrylamide gel electrophoresis the enzyme produced a single protein band (Mr 30 000 +/- 3000 Da). Isoelectric focusing revealed that the enzyme has several multiple forms (pI 6.9, 7.5, 8,0). The enzyme is a glycoprotein containing 5.9% of carbohydrates; the mannose to galactose ratio is 1:3. The amino acid composition of the enzyme was studied. The proteinase splits an oxidized insulin B-chain and synthetic substrates. The pH optimum is 3.2. The enzyme is immunologically identical to porcine spleen cathepsin D.
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PMID:[Proteinases of small intestine enterocytes of swine. Purification and properties of aspartyl proteinase similar to cathepsin D]. 393 2

A pepsinogen C-like acid protease zymogen was found in Japanese monkey prostate extract and seminal plasma by means of the double immunodiffusion method using rabbit anti-pepsinogen C antiserum, and was purified from the prostate by a combination of ammonium sulfate fractionation, DEAE-Sephacel chromatography, Sephadex G-100 gel filtration, and immunoadsorption to an anti-pepsinogen C column. The zymogen was purified 6,400-fold in a yield of 13.1%. The purified zymogen gave a single band on polyacrylamide gel electrophoresis both in the presence and absence of sodium dodecyl sulfate. The zymogen was converted to the active form by acid treatment at pH 2.8 for 4 h with concurrent reduction of the molecular weight from 41,000 to 36,000. By the double immunodiffusion method, prostate pepsinogen C-like acid protease zymogen, pepsinogen C, lung procathepsin D-II, and their active forms gave a single, fused precipitin line in agar plate with anti-pepsinogen C antiserum, which did not react with cathepsin D and pepsinogen A. Furthermore, the optimal pH of 2.5-3.0, the effect of pepstatin on the activity, and the amino acid compositions were also in good agreement among these three zymogens, showing that they are very similar protease zymogens.
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PMID:Purification of Japanese monkey prostate acid protease zymogen and its identification as a pepsinogen C-like zymogen. 393 48

Rabbit cardiac cathepsin D is initially synthesized as an inactive, apparent molecular weight (Mr) 53,000, pI 6.6 precursor (procathepsin D) that is proteolytically processed during intracellular transport to produce the Mr 48,000 isoforms of active cathepsin D found in cardiac lysosomes. To examine potential proteases responsible for intracellular proteolytic processing, biosynthetically labeled procathepsin D was isolated from rabbit ventricular tissue perfused for 30 min with [35S]methionine. Procathepsin D was then incubated in vitro (40 degrees C, 1-240 min) with active cathepsin D, papain, and cathepsin B, either singly or sequentially, and the reaction products analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and two-dimensional electrophoresis. Incubation of 35S-labeled procathepsin D with active cathepsin D produced a single reaction product (Mr 51,000; pI 6.2). This limited proteolysis occurred at pH 3-5 and was inhibited by pepstatin. Incubation of 35S-labeled procathepsin D with papain or cathepsin B produced a major reaction product (Mr 48,000; pI 6.4) and a minor form (Mr 50,000; pI 6.0). These reactions occurred at pH 4-7 and were inhibited by leupeptin but not pepstatin. Only the Mr 48,000, pI 6.4 products of papain and cathepsin B-mediated proteolysis comigrated with the most basic isoform of active cathepsin D found in cardiac tissue. In addition, the Mr 51,000 intermediate produced by cathepsin D was susceptible to further limited proteolysis by cysteine proteases with resultant production of a Mr 48,000 product. Thus the intracellular proteolytic processing of rabbit cardiac procathepsin D does not result solely from autocatalysis but requires at least one other protease, possibly cathepsin B.
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PMID:Limited proteolysis of rabbit cardiac procathepsin D in a cell-free system. 396 72

Cathepsin D was purified from the lactating rabbit mammary gland by a rapid procedure, which included fractionation with (NH4)2SO4, acid precipitation, double affinity chromatography on pepstatin-Sepharose 4B and gel filtration on Sephadex G-100, resulting in approximately 360-fold purification of the enzyme over the homogenate and approximately 16% recovery. After isoelectric focusing, the enzyme dissociated into four (pI 5.8, 6.3, 6.5 and 7.2) multiple forms, but appeared homogeneous on polyacrylamide gel electrophoresis. Cathepsin D has a Mr of 45 kDa as determined by Sephadex G-100 column chromatography. On sodium dodecylsulfate/polyacrylamide gel electrophoresis the enzyme gave a single protein band, corresponding to Mr of 45 kDa. The amino acid composition of the enzyme is similar to that of cathepsins D from other tissues. A single N-terminal amino acid was glycine. Cathepsin D contains 6.4% carbohydrates consisting of mannose, galactose, fucose and glucosamine at a ratio of 3:9:2:2. Cathepsin D is inhibited by pepstatin with Ki of 2.5 X 10(-9) M and irreversibly by N-diazoacetyl-N'-2.4-dinitrophenyl-ethylene diamine. The enzyme hydrolyzes bovine hemoglobin with the maximal activity at pH 3.0 with Km = 10(-5) M and HLeu-Ser-Phe(NO2)-Nle-Ala-Leu-OMe with Km = 4 X 10(-5) M and Rcat = 0.95 s-1. The major cleavage sites were Leu15-Tyr16, Phe24-Phe25 and Phe25-Tyr26 during hydrolysis of the oxidized insulin B-chain by cathepsin D.
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PMID:[Purification and properties of cathepsin D from the mammary glands of lactating rabbits]. 400 22

1. Cathepsin B1 was purified from human liver by a method involving autolysis, fractional precipitation with acetone, adsorption on, and stepwise elution from, CM-cellulose and an organomercurial adsorbent, gel chromatography and finally equilibrium chromatography on CM-cellulose. 2. The early stages of the procedure, including the use of the organomercurial adsorbent, were suitable for the simultaneous isolation of cathepsin D. The two cathepsins were sharply separated on the organomercurial column, and particular attention was given to the method for the preparation and use of this adsorbent. 3. A method is described for the staining of analytical isoelectric-focusing gels for cathepsin B1 activity, as well as protein. By this method it was shown that cathepsin B1 was represented by at least six isoenzymes during the greater part of the purification procedure. After the gel-chromatography step this group of isoenzymes was obtained essentially free of other proteins, in good yield. The isoenzymes were resolved from this mixture by chromatography on CM-cellulose. The purified enzyme was stable for several weeks at slightly acid pH values in the absence of thiol compounds; it was unstable above pH7. 4. The pI values of the isoenzymes of cathepsin B1 extended from pH4.5 to 5.5, that of the major isoenzyme tending to increase from 5.0 to 5.2 during the purification procedure. Gel chromatography indicated a molecular weight of 27500 for all of the isoenzymes, whereas polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate gave a value of 24000. 5. An antiserum raised in sheep against the purified enzyme reacted specifically with the alkali-denatured molecule. Purified cathepsin B1 contained no material precipitable by an anti-(human cathepsin D) serum. 6. The enzyme hydrolysed several N-substituted derivatives of l-arginine 2-naphthylamide, as well as haemoglobin, azo-haemoglobin, azo-globin and azo-casein. Greatest activity was obtained near pH6.0. 7. The sensitivity of human cathepsin B1 to chemical inhibitors was generally similar to that of other thiol proteinases. The enzyme was inactivated by the chloromethyl ketones derived from tosylphenylalanine, tosyl-lysine, acetyltetra-alanine and acetyldialanylprolylalanine. 8. The hydrolysis of alpha-N-benzoyl-dl-arginine 2-naphthylamide by extracts of human liver at pH6 was attributable entirely to cathepsin B1.
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PMID:Human cathepsin B1. Purification and some properties of the enzyme. 412 67

Candida albicans was able to produce a keratinolytic proteinase (KPase) when cultivated in a medium containing human stratum corneum as a nitrogen source. The KPase was purified to 108.5-fold by ion-exchange chromatography and gel filtration. The molecular weight of the enzyme was estimated to be 42,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and gel filtration through Sephacryl S-200, while the isoelectric point was determined to be at pH 4.5. The enzyme had an optimum pH of 4.0 and was "inactive" below pH 2.5 and above pH 6.0. The activity of KPase after preincubation at various temperatures was stable up to 50 degrees C. The keratinolytic activity was not affected by the addition of nonionic detergents and divalent cations. The enzyme was a glycoprotein and contained a high content of aspartic acid residues (172/1000). Pepstatin and chymostatin inhibited the activity in a dose-dependent manner; however, neither the other group specific inhibitors tested nor the pepsin specific inhibitors, DAN or EPNP, showed any effect on the enzyme. From these inhibitory profiles, this enzyme was determined to be a carboxyl proteinase such as cathepsin D. Among the various substrates for proteolytic enzymes, KPase digested human stratum corneum as much as albumin and hemoglobin. In the three fractions (water soluble, keratin filamentous, and membranous) prepared from human stratum corneum, the keratin filamentous fraction was more susceptible to degradation by KPase than the other two fractions were. KPase also digested much less human fingernail (13%) than human stratum corneum, but did not show any signs of there being any digestion of human scalp hair. These studies suggest that KPase from C. albicans may play an important role in superficial infection by affecting the human stratum corneum of the skin and nail.
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PMID:Isolation and characterization of proteinase from Candida albicans: substrate specificity. 620 88

In cultured human fibroblasts we observed that monensin, a Na+/H+-exchanging ionophore, (i) inhibits mannose 6-phosphate-sensitive endocytosis of a lysosomal enzyme, (ii) enhances secretion of the precursor of cathepsin D, while inhibiting secretion of the precursors of beta-hexosaminidase, (iii) induces secretion of mature beta-hexosaminidase and mature cathepsin D, and (iv) inhibits carbohydrate processing in and proteolytic maturation of the precursors remaining within the cells; this last effect appears to be secondary to an inhibition of the transport of the precursors. If the treated cells are transferred to a monensin-free medium, about half of the accumulated precursors are secreted, and the intracellular enzyme is converted into the mature form. Monensin blocks formation of complex oligosaccharides in lysosomal enzymes. In the presence of monensin, total phosphorylation of glycoproteins is partially inhibited, whereas the secreted glycoproteins are enriched in the phosphorylated species. The suggested inhibition by monensin of the transport within the Golgi apparatus [Tartakoff (1980) Int. Rev. Exp. Pathol. 22, 227-250] may be the cause of some of the effects observed in the present study (iv). Other effects (i, ii) are rather explained by interference by monensin with the acidification in the lysosomal and prelysosomal compartments, which appears to be necessary for the transport of endocytosed and of newly synthesized lysosomal enzymes.
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PMID:Effect of monensin on intracellular transport and receptor-mediated endocytosis of lysosomal enzymes. 623 17

There are two types of enzymes in tissues leading to angiotensin formation: a) those resulting in the formation of angiotensin I, such as renin and cathepsin D, the presence of which is now well established for brain tissue and b) Those leading to the direct formation of angiotensin II without the angiotensin I step, such as cathepsin G and tonin. Recent findings concerning tonin, a serine protease, are described: a) 80% of its amino acid sequence, b) its different characteristics from other serine proteases, from renin, cathepsin D and the angiotensin I converting enzyme, c) the activation of inactive renin, d) its involvement in the 1K-1C hypertensive rats, e) the demonstration of its presence in the distal tubular cells of the rat kidney, and finally, f) its presence in urine and the influence of age and of sodium intake on its urinary excretion.
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PMID:Extrarenal angiotensin-forming enzymes. 631 65

We have studied the dog as a potential model for the human plasma prorenin-renin system. On a regular sodium intake, healthy conscious dogs apparently have a much lower plasma renin activity (PRA) than healthy human volunteers. Cryoactivation of prorenin is virtually absent in dogs, in contrast to that in humans, but becomes more effective after preacidification of the plasma. The concentration of trypsin required for optimal activation of prorenin is 6 to 10 times higher for dog plasma, revealing a prorenin:renin ratio about 10 times greater than in humans. Dialysis of posttryptic plasma decreases the PRA, but it remains 5 times higher than in pretryptic plasma, indicating that activation is not totally dependent on any renin system component that has been rendered dialyzable by trypsin, e.g., substrate converted to tetradecapeptide (TDP). This argues against the view that tryptic activation is attributable to angiotensin production from TDP by the action of cathepsin D, rather than from new renin converted from prorenin. The posttryptic increase in PRA is evident whether plasma incubation is carried out at pH 6.0 or at 7.4, and can be largely blocked by pepstatin, which also implicates a prorenin-renin mechanism rather than TDP-cathepsin. The low PRA in dogs, the negligible cryoactivation and its improvement by preacidification, and the requirement and tolerance of high trypsin concentrations, all point to greater protease inhibition in dog plasma and/or departures from the enzyme(s) responsible for human prorenin activation. Moreover, the tryptic activation of prorenin is not completed quickly as in human plasma, but carries over into the posttryptic stage of angiotensin generation, even in the presence of excess soybean trypsin inhibitor (SBTI), and other potent inhibitors. Such ongoing prorenin activation cannot be attributed only to trypsin itself, nor to kallikrein (both are inhibited by SBTI), but rather to some other enzyme(s) derived by the action of trypsin. This new prorenin convertase activity (possibly renin itself) can be effectively transferred from trypsinized to control dog plasma, in which it greatly accelerates prorenin activation. Thus, contrary to other reports, dog plasma has a high content of activatable prorenin, and with appropriate methodological changes, the dog can be used as an animal model for physiological and biochemical studies of the prorenin-renin system.
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PMID:Plasma prorenin in humans and dogs. Species differences and further evidence of a systemic activation cascade. 634 Dec 16

Renin and cathepsin D were purified by seven-step procedures involving five steps common to both enzymes. These common five steps were extraction of freeze-dried kidney powder in 30% methoxyethanol-water, diethylaminoethyl-cellulose (DEAE-cellulose) batch absorption and elution, pepstatin-aminohexyl-Sepharose chromatography, Sephadex G-100 chromatography, and DEAE-cellulose chromatography. The renin component was purified further by passage through an anti-rat spleen cathepsin D immunoglobulin G-Sepharose (IgG-Sepharose) column followed by carboxymethyl-Sephadex (CM-Sepharose) chromatography which separated two renin components. Cathepsin D activity obtained by the fifth step was purified by passage through an anti-rat kidney renin IgG-Sepharose column followed by DEAE-Sephacel chromatography which separated three cathepsin D components. The homogeneity of renin and cathepsin D preparations was demonstrated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. The two components of renins showed molecular weights of 42 000 and 36 000 by gel filtration and 38 000 and 36 000 by SDS gel electrophoresis, respectively. They showed isoelectric points of 5.35 and 5.65 by electrofocusing in 5% polyacrylamide gels. Their optimum pHs of enzyme activity were 6.5 as determined by using nephrectomized rat plasma as a substrate. Their specific angiotensin I (Ang I) generation activities were 158 and 146 micrograms of Ang I (microgram of protein)-1 h-1, respectively, which correspond to 1100 and 1020 Goldblatt units (mg of protein)-1 h-1. The three cathepsins showed molecular weights of 41 000, 43 000, and 41 000 by gel filtration and 46 000, 45 000, and 46 000 by SDS gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Rat kidney renin and cathepsin D: purification and comparison of properties. 636 Feb 7


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